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Design of an Integrated Monitoring System
Module of Remote Sensing and GIS Integration Course 2014
Lammert Kooistra, Ron van Lammeren, Martin Herold,
Ben DeVries, Eskender Beza and Richard Fuchs
RGIC general set-up
Academic Consultancy Training (ACT) project (20 d) Phase 1 Phase 2 Phase 3
Project proposal Analysis Report & Presentation
+ excursions: 2 days
Management skills
Project management
Communication (2 d)
Geo-skills GSNS LBS
Field Spectroscopy
(4 d)
Design of Integrated Monitoring System (DIMS: 9 d)
Learning objectives for DIMS
Understand the role of geo-information science in integrated
monitoring of the system Earth;
Explain which concepts and techniques for integrated
monitoring systems are currently applied and for which earth
system processes;
Prepare a design for integrated monitoring system for a
selected beneficial area taking into account state-of-the-art
developments in the field of geo-information science;
Develop and implement a validation and fieldwork plan to
assess the quality of the main data sources of this monitoring
system;
Demonstrate the use of proper visualization techniques for
effective communication of the information in the monitoring
system.
Program kick-meeting DIMS module
Time Title Presenter
8:30 – 9:00 Integrated Monitoring Systems: concepts and approaches Lammert Kooistra
9:00 – 9:30 Global context and societal benefits of geo-information and
earth observation in monitoring applications
Martin Herold
9:30 – 9:45 Break
9:45 – 10:05 Towards an Integrated Forest Monitoring System for REDD+: The Case of Kafa, Ethiopia
Ben DeVries
10:05 – 10:25 Opportunities for Crowdsourcing approach to collect
biophysical and socio-economic factors for yield gap analysis
Eskender Beza
10:25 – 10:45 Communicating research: storytelling with maps Richards Fuchs
10:45 – 11:00 Discussion
11:00 – 11:30 Introduction to the Assignment Design of an Integrated
Monitoring System
Lammert Kooistra
11:30 – 15:30 Brainstorm on selection of benefit area and monitoring system requirements
Project teams
15:30 – 16:30 Feedback session: introduction pitch (3 minutes) per team
on selected integrated monitoring system
Project teams
Integrated Monitoring Systems:
Concepts and Approaches
Lammert Kooistra
Laboratory of Geo-Information Science and Remote Sensing
Wageningen University
DIMS Module of Remote Sensing and GIS Integration Course 2013
Environmental Resource Management in the Anthropocene Era
Climate change
Land use change
Invasive species
disasters: flooding, hurricanes, …
Need for spatial-temporal monitoring
Not only WHAT and WHERE but also WHEN
& real-time !?
User requirements for earth system monitoring Tim
e
hour –
day –
week –
month –
quarter –
year –
decade –
Space
–
–
–
–
–
– local regional state/country continental global
Up-/Down- Scaling
Agricultural parcel: precision agriculture (farmer) Nature reserve: nature management (nature service)
River catchments: flood protection (river & water board) Nature reserves: fire protection (forest service)
Climate change: carbon accounting (national government) Invasive species
Drought monitoring Biodiversity
Climate change Land use
Structural monitoring service
Event monitoring service
Developments in Remote Sensing
Long term time-series
Range of sensor types
Range of products and services
Global organization and cooperation
Improved (web-based) accessibility
Also for non-experts
Standards and quality control
Near-real time availability
Development of early warning systems
Developments in Geo-Sensor Networks
Traditional:
● Broad range of sensor networks
● Stable and well organized
● Often not real-time (manual or data-logger)
Trends:
● Miniaturization of microelectronics
● Wireless communication
● Developments of new materials & sensors
Consequences:
● Embedding devices into almost any man-made and some natural devices, and
● connecting the device to an infinite network of other devices, to perform tasks, without human intervention.
● Information technology becomes omnipresent.
Crossbow Mica Mote
Source: Nittel, Sensors, 2009
Developments in Mobile Sensing
All kind of platforms combined with different sensor types
● Difficult accessible areas
● Disaster monitoring (flexibility)
● Mobile processes: traffic jams or animal tracking
Increasing autonomy of sensor network
Adaptive learning
Developments into human sensing:
● Use of mobile phones
● Citizen observatories
● Crowd sourcing
Opportunities for Integrated Sensing Tim
e
hour –
day –
week –
month –
quarter –
year –
decade –
Space
–
–
–
–
–
– local regional state/country continental global
Up-/Down- Scaling
Agricultural parcel: precision agriculture (farmer) Nature reserve: nature management (nature service)
River catchments: flood protection (river & water board) Nature reserves: fire protection (forest service)
Climate change: carbon accounting (national government) Invasive species
Drought monitoring Biodiversity
Climate change Land use
Structural monitoring service
Event monitoring service
Opportunities for Integrated Sensing Tim
e
hour –
day –
week –
month –
quarter –
year –
decade –
Space
–
–
–
–
–
– local regional state/country continental global
Up-/Down- Scaling
Agricultural parcel: precision agriculture (farmer) Nature reserve: nature management (nature service)
River catchments: flood protection (river & water board) Nature reserves: fire protection (forest service)
Climate change: carbon accounting (national government) Invasive species
Drought monitoring Biodiversity
Climate change Land use
Structural monitoring service
Event monitoring service
Concepts for spatio-temporal data organisation
Digital Earth (Craglia et al., 2012):
● ‘a multi-resolution, three-dimensional representation of the planet that
would make it possible to find, visualise and make sense of vast amounts
of geo-referenced information on physical and social environments’
Sensor Webs (Teillet, 2010):
● ‘a system of autonomous, wireless, intra-communicating, spatially-
distributed sensor pods that can be deployed to monitor and explore new
environments, a smart macro instrument for coordinated sensing’
Global Earth Observation System of Systems (Lautenbacher, 2006):
● ‘The focus of GEOSS is to produce societal benefits through more
coordinated observations, better data management, increased data
sharing, and application to societal needs.’
Global Earth Observation System of Systems: GEOSS
A Global, Coordinated, Comprehensive and Sustained System of Earth Observing Systems
GEO is a voluntary partnership of 72 governments and the European Commission, 52 intergovernmental organizations (Feb 2008)
source: www.earthobservations.org
User driven approach Interoperability
arrangements Web portal and
clearing house Support new
observation methods Dissemination
knowledge
Monitoring and indicator frameworks
Essential Climate Variables (ECVs)
Essential Biodiversity Variables (EBVs)
Plant traits (System Ecology)
Ecosystem Services (Biodiversity)
MRV REDD (Forestry)
The New Production of Knowledge
Mode 1 Mode 2
• Academic context • Disciplinary • Homogeneity • Autonomy • Traditional quality control
(peer review)
• Context of application • Trans disciplinary • Heterogeneity • Reflexity/social
accountability • Novel quality control
Source: Hessels et.al. 2008 after Gibbons 1994
Position of DIMS and ACT
Pure basic research
Use-inspired research
Pure applied research
Quest
for
fundam
enta
l unders
tandin
g
Considerations of use
Yes
Yes
No
No
Source: Stokes 1997
DIMS
ACT
PhD/MSc thesis
Triple helix
University – Government – Industry
Complex relationship
● Confusion of roles
● Simultaneously Competing and
Cooperating
Silicon Valley, Food Valley, Brainport
Eindhoven, Mechatronic Valley, Health
Valley
Science became less autonomous
More customer-contractor relations
“Market based” system
Application: Precision agriculture
Problem: Derive operational indicators for crop status/health over the growing season
Research challenges:
● Indicators: VIs -> temporal signal -> Fs -> crop models
● Sensor integration: near-remote sensing, platforms (both vegetation and soil)
● Backward integration: user friendly services
Partners: BLGG AgroXpertus, TTW, Terrasphere, vd Borne Aardappelen, WUR-PRI/PPO, MTT Finland
11 June 23 June 5 July 14 juli 19 aug 6 sept
Project Interreg IV A SMART INSPECTORS
31 May
Integrated sensor approach for PA
close sensing
+ flexible acquisition
+ active system
– no processing standards
– point observations
spatial-temporal- spectral
scaling model
remote sensing whole parcel +
preprocessing + clouds –
not all days –
high-frequency time-series
UAVs to support environmental management
detection
diagnosis & decision rules
management activity
Source: report van der Voet, 2012
Summary
Integrated monitoring includes:
●New concepts for organization
●State-of-the-art observation or sensing techniques
●Explicitly taking users and beneficiaries into account (societal context)
●Combining different societal benefit areas
References
Craglia et al., 2012. Digital Earth 2020: towards the vision for the next decade. International Journal of Digital Earth 5: 4-21.
Fritz, S., McCallum, I., Schill, C., Perger, C., See, L., Schepaschenko, D., van de Velde, M., Kraxner, F., Obersteiner, M. (2012). Geo-Wiki: An online platform for improving global land cover. Environmental Modelling and Software 31: 110-123.
Lautenbacher, C.E. (2006). The Global Earth Observation System of Systems: Science Serving Society. Space Policy 22: 8-11.
Kooistra, L.; Thessler, S.; Bregt, A.K. (2009). User requirements and future expectations for geosensor networks – an assessment. In: GeoSensor Networks 2009 / Trigoni, N., Markham, A., Nawaz, S., . - Berlin-Heidelberg : Springer, (Lecture Notes in Computer Science 5659) .
Ligtenberg, A.; Kooistra, L. (2009). Sensing a changing world. Sensors 9: 6819 - 6822.
Nittel, S. (2009). A Survey of Geosensor Networks: Advances in Dynamic Environmental Monitoring. Sensors 9: 5664-5678.
Teillet, P. (2010). Sensor Webs: A geostrategic technology for integrated earth sensing. IEEE JSTARS 3: 47-80.
